Deep learning-based behavioral drift modeling for continuous biometric authentication
No Thumbnail Available
Date
2026-01
Journal Title
Journal ISSN
Volume Title
Publisher
BRAC University
Abstract
Ascending technologies like the concepts of robotics, artificial intelligence (AI), the
concepts of smart devices and the Internet of Things (IoT) have been assimilated
into traditional and indispensable physical, biological and digital systems incubating
the fourth industrial revolution. Following the era where the attainability of AI has
become ubiquitous, vitality has risen to integrate the smartness of AI into traditional
authentication systems in order to strengthen the security and develop a resilient
and robust barrier between the infiltrator and the delicate systems. The integration
of unimodal physiological biometrics along with the previous password systems
served the purpose to a certain extent. But the widespread use of AI has given the
intruders an easier access to breach the seclusion of systems, raising a massive question
for the security, especially in this era of digital transactions, banking, healthcare
systems and academic assessments. There comes the necessity of initiating the utilization
of behavioral biometric authentication that integrates the behavioral drift of
individuals so that impostors relying on static templates and physiological traits like
fingerprints are recognized and the system remains decontaminated. In this regard,
this research proposes a two-level keystroke dynamics authentication system that
provides defense-in-depth security through continuous behavioral drift monitoring.
Level 1 employs fixed-text password authentication using Temporal Convolutional
Networks (TCN) with contrastive learning and population-based training (PBT),
achieving 3.77% EER for high-security login verification. Upon successful authentication,
Level 2 continuously monitors user typing during natural free-text sessions
using a 4-Model Deep Learning Ensemble. If suspicious behavioral drift is detected
during monitoring, the system re-authenticates the user by returning to Level 1,
providing a feedback loop against session hijacking and behavioral anomalies. The
system explicitly models long-term behavioral drift through the fixed-text component’s
PBT mechanism, which adapts to temporal variations in password typing
patterns. This research leverages free-text (Buffalo dataset) and fixed-text (GREYC
dataset) keystroke dynamics datasets, extracting temporal and spatial features
including hold times, up-down latencies, down-down intervals, and trigram
patterns. The final system achieves 96%+ accuracy for fixed-text authentication
(3.77% EER) and 83.53% True Acceptance Rate (TAR) at 5% False Acceptance
Rate (FAR) for free-text continuous authentication (10.05% EER), demonstrating
superior performance and strong resistance to impostor attacks through continuous
behavioral monitoring.
Description
Cataloged from PDF version of thesis.
Includes bibliographical references (pages 144-147).
This thesis is submitted in partial fulfillment of the requirements for the degree of Bachelor of Science in Computer Science, 2026.
Includes bibliographical references (pages 144-147).
This thesis is submitted in partial fulfillment of the requirements for the degree of Bachelor of Science in Computer Science, 2026.
Keywords
Continuous authentication, Behavioral biometrics, Keystroke dynamics, Deep learning, Ensemble learning
